Post on 10-Oct-2014
Yair Moshe
Department of Electrical Engineering, Technion – IITSignal and Image Processing Laboratory
Nov., 2010
Advanced MATLAB®
Graphics and GUI
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Outline
• Graphics
• Animation
• Image and Video
• Handle Graphics Objects
• Creating GUI using GUIDE
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2-D Plotting
x=0:.1:2*pi;y=sin(x);plot(x,y)grid onhold on
plot(x, exp(-x), 'r:*')hold offaxis([0 2*pi 0 1])
title('2-D Plot')
xlabel('Time')
ylabel('F(t)')
text(pi/3, sin(pi/3), '<--sin(\pi/3) ')
legend('Sine Wave','Decaying Exponential')
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Line Specification
Specifier Line Color Specifier Marker
r red . point
g green o circle
b blue x cross
c cyan + plus
m magenta * asterix
y yellow s square
k black d diamond
w white v triangle down
Specifier Line Style ^ triangle up
- solid < triangle left
-- dashed > triangle right
: dotted p pentagram
:. dash-dot h hexagram
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The Figure Window
The figure window contains useful actions in its menuand toolbars:• Zooming in and out • Panning• Rotating 3-D axes (and other camera actions)• Copying & pasting• Plot Edit Mode• Plot tools (interactive plotting)
– Figure Palette– Plot Browser– Property Inspector
• Data Cursor Mode• Data brushing and linking
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The Figure Window
• Generate M-Code to reproduce the figure
• Saving & exporting
– Figures can be saved in a binary .fig file format
– Figures can be exported to many standard graphics file formats etc., EPS (recommended),TIFF, JPEG, GIF, PNG, BMP, EMF.
• Printing
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Subplots & Scales for Axes
subplot(2,2,1)x=0:.1:2*pi;plot(x, exp(-x))
subplot(2,2,2)semilogy(x, exp(-x))
subplot(2,2,3)t = 0:900;z1 = 1000*exp(-0.005*t);z2 = sin(0.005*t);plotyy(t,z1,t,z2,'semilogy','plot');
subplot(2,2,4)plot(peaks)
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Interactive Plotting
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Data Brushing and Linking
• Data Brushing
– Manually select observations on an interactive data display
– Can select, remove, and replace individual data values
• Data Linking
– Linked plots visibly respond to changes in the current workspace variables they display and vice versa
• Each one of these tools is useful by itself but when used together they are very powerful
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Data Statistics & Curve Fitting
• Data Statistics Tool
– Calculates basic statistics about the central tendency and variability of data plotted in a graph
– Plots any of the statistics the a graph
• Basic Fitting Interface
– Fits data using a spline interpolant, a shape-preserving interpolant, or a polynomial up to degree 10
– Plots multiple fits simultaneously for a given data set
– Examines the numerical results of a fit
– Annotates the plot with the numerical fit results and the norm of residuals
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3-D Plotting
z = 0:0.1:10*pi;
x = exp(-z/20).*cos(z);
y = exp(-z/20).*sin(z);
plot3(x,y,z,'LineWidth',2)
grid on
xlabel('x')
ylabel('y')
zlabel('z')
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Specialized Plotting Routines
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3-D Meshes and Surfaces
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3-D Meshes and Surfaces
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3-D Meshes and Surfaces
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Outline
• Graphics
• Animation
• Image and Video
• Handle Graphics Objects
• Creating GUI using GUIDE
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Animation
MATLAB provides two ways of generating moving,
animated graphics:
1. On the fly - Continually erase and then redraw the objects on the screen, making incremental changes with each redraw
2. Frame by frame capture and playback - Save a number of different pictures and then play them back as a movie
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On the Fly Animation, 1st example
% initialize surface objectx = -pi:0.1:pi;xsize = size(x,2);
f = zeros(xsize);for y = 1:xsize
f(:,y) = cos(y/xsize*pi) + sin(x);end
% draw surface first timehSurface = surface(f, 'LineStyle', 'none');view(3); % set the default 3D view
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On the Fly Animation, 1st example
% function drawing loopfor j=0:0.3:10
% update surface functionfor y = 1:xsize
f(:,y) = cos(y/xsize*pi+j) + sin(x+j);end
% update surface ZDataset(hSurface, 'ZData', f);
drawnow;end
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On the Fly Animation, 2nd example
t = 0:pi/20:2*pi;y = exp(sin(t));h = plot(t,y,'YDataSource','y');for k = 1:.1:10
y = exp(sin(t.*k));refreshdata(h,'caller') % Evaluate y in the function workspacedrawnow; pause(.1)
end
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Frame by Frame Animation
[x,y] = meshgrid([-10:0.5:10]);for j = 1:15
z = bessel(0, (j-1)*0.2 + sqrt(x.^2 +y.^2));surf(x,y,z)axis([-10 10 -10 10 -.5 1])M(j) = getframe;
end
frame_order = [1:15 14:-1:1];number_repeats = 5;movie(M, [number_repeats frame_order]);
Example of frame by frame movie creation and playing:
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Outline
• Graphics
• Animation
• Image and Video
• Handle Graphics Objects
• Creating GUI using GUIDE
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Images
[x,map]=...
imread('peppers.png');
image(x)
colormap(map)
• Image I/O
– imread, imwrite, iminfo
• Image display
– image – Display
– imagesc – Scale and display
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Images
a = magic(4);
image(a);
map = hsv(16);
colormap(map)
colorbar
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Image Processing Toolbox
• Image display
– imshow – Display
– subimage – Display multiple images in a single figure even if they have different colormaps
• Image exploration
– imtool – Provides tools for pixel information, pixel region, distance, image information, adjust contrast, crop image, and display range
• Movie Player
– implay – Play movie, video, or image sequence
– Multi-frame to movie
– immovie - Make MATLAB movie from a multiframe image
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Video
• Media Player (from Simulink)
– mplay - View video from MATLAB workspace, multimedia file, or Simulink model
• AVI
– aviread, avifile, addframe, close, aviinfo – Allows frame-by-frame manipulation of AVI files
– movie2avi – Make AVI file from MATLAB movie
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Video
• Multimedia reader
– mmreader, read, mmfileinfo - Allows frame-by-frame manipulation of video files
– Newer and better than counterpart AVI functions
– Supports many formats using installed Windows video codecs
• Video reader & writer
– videoReader, videoWriter - Read and write video data from a file
– videoReader replaces mmreader
– videoWriter replaces counterpart AVI functions
– VideoWriter supports only 'Motion JPEG AVI' and 'Uncompressed AVI‘
– 3rd party toolbox: videoIO
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Related Toolboxes
• Image Acquisition Toolbox
– Acquire images and video
– Support for a large range of imaging devices
• Video and Image Processing Blockset
– Multimedia I/O, video viewer, and display blocks
– Can work in real-time
– Can read from / write to MATLAB workspace
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Outline
• Graphics
• Animation
• Image and Video
• Handle Graphics Objects
• Creating GUI using GUIDE
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Handle Graphics Objects
• Handle Graphics is an object-oriented structure for creating, manipulating and displaying graphics
• Graphics objects are the basic drawing elements used in MATLAB
• Every graphics object has:
– A unique identifier, called a handle
– A set of characteristics, called properties
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Graphics Objects Hierarchy
Objects are organized into a hierarchy:
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Core Graphics Objects
Axes (2-D) Patch
Surface
Axes (3-D)
Image
FigureLine Text
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Composite Graphics Objects
• Composite Objects are core objects that have been grouped together to provide a more convenient interface
• Plot objects– areaseries, barseries, contourgroup, errorbarseries, lineseries,
quivergroup, scattergroup, stairseries, stemseries, surfaceplot
• Group objects– hggroup – Enables to control visibility or selectability of a group
of objects
– hgtransform – Enables to transform (etc., rotate, translate, scale) a group of objects
• Annotation objects– Created in a hidden axes that extends the full size of the figure
– Enables to specify the locations anywhere in the figure using normalized coordinates
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Obtaining an Object’s Handle
• Upon creation, for example:
– h = plot(x_data, y_data, …)
• Using utility functions:
– 0 - root object handle (the screen)
– gcf – returns the handle of the current figure
– gca - returns the handle of the current axis in the current figure
– gco - returns the handle of the current object in the current figure
– gcbo - returns the handle of the object whose callback is currently executing
– gcbf - returns the handle of the figure that contains the object whose callback is currently executing
– findobj(handles,’PropertyName’,PropertyValue) – return objects with specific properties
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Setting and Getting Properties
• Return a list of all object properties and their current values:– get(handle)
• Return current value of an object property:– get(handle, ‘PropertyName’)
– Example: get(gcf, 'Color')
• Return a list of all user-settable object properties and their current values:– set(handle)
• Return a list of all possible values for an object property:– set(handle,’PropertyName’)
– Example: set(gca, 'XDir')
• Set an object property to a new value:– set(handle, ‘PropertyName’, ‘NewPropertyValue’)
– Example: set(gca, 'XDir', 'Reverse')
• All the above can also be done (but not at runtime) using the Property Editor
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Example – Specifying Figure Position
space = 5;top_space = 80;scn_size = get(0,'ScreenSize');
pos1 = [space, 2/3*scn_size(4) + space,...scn_size(3)/2 - 2*space, scn_size(4)/3 - (top_space + space)];
pos2 = [pos1(1) + scn_size(3)/2, pos1(2),...pos1(3), pos1(4)];
h1 = figure(1);peaks;h2 = figure(2);membrane;
set(h1, 'Position', pos1) set(h2, 'Position', pos2)
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Example – Background Image
% Create background axes and move them to the backgroundhback = axes('units','normalized','position',[0 0 1 1]); uistack(hback,'bottom');
% Load background image and display it[back map]=imread('sipl.gif');image(back)colormap(map)
% Turn the handlevisibility off so that we don't inadvertently plot into% the axes again. Also, make the axes invisibleset(hback,'handlevisibility','off','visible','off')
% Now we can use the figure as requiredaxes('position',[0.1,0.1,0.85,0.35])plot(rand(10))
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Outline
• Graphics
• Animation
• Image and Video
• Handle Graphics Objects
• Creating GUI using GUIDE
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What is GUIDE?
• GUIDE is MATLAB’s Graphical User Interface (GUI) Development Environment
• GUIDE stores GUIs in two files:
– .fig file - Contains a complete description of the GUI figure layout and the GUI components
• Changes to this file are made in the Layout Editor
– .m file - Contains the code that controls the GUI
• Initialization code and callbacks
• You can program the behavior of the GUI in this file using the M-file
Editor
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Creating a GUI
Typical stages of creating a GUI are:
1. Designing the GUI
2. Laying out the GUI
– Using the Layout Editor
3. Programming the GUI
– Writing callbacks in the M-file Editor
4. Saving and Running the GUI
It is also possible to create a GUI programmatically
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The Layout Editor
Component Palette
Align Objects
M-file Editor
Run GUI
Object Browser
Property Inspector
Layout Area
Resize Box
Menu Editor
Tab Order Editor
Toolbar Editor
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Hands-On GUIDE Example
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Callbacks
• A callback is a function that executes when a specific event occurs on a graphics object
– Also called event handler in some programming languages
• A property of a graphics object
– All objects: ButtonDownFnc, CreateFnc, DeleteFnc
– User interface controls: Callback, KeyPressFcn,
– Figure: CloseRequestFcn, KeyPressFcn, KeyReleaseFcn, ResizeFcn, WindowButtonDownFcn, WindowButtonMotionFcn, WindowButtonUpFcn, WindowKeyPressFcn, WindowKeyReleaseFcn, WindowScrollWheelFcn
– …
• Stored in the GUI’s M-file
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Writing Callbacks
A callback is usually made of the following stages:
1. Getting the handle of the object initiating the action (the object provides event / information / values)
2. Getting the handles of the objects being affected (the object whose properties are to be changed)
3. Getting necessary information / values
4. Doing some calculations and processing
5. Setting relevant object properties to effect action
6. Save any changes that have been made to the handles structure by using
guidata(hObject, handles)– hObject is the handle to the component object that executes
the callback
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Writing Callbacks
…
% --- Executes on button press in plot_button.function plot_button_Callback(hObject, eventdata, handles)% hObject handle to plot_button (see GCBO)% eventdata reserved - to be defined in a future version of MATLAB% handles structure with handles and user data (see GUIDATA)
% Get user input from GUIf1 = str2double(get(handles.f1_input,'String'));f2 = str2double(get(handles.f2_input,'String'));t = eval(get(handles.t_input,'String'));
% Calculate data…
% Create frequency plotaxes(handles.frequency_axes) % Select the proper axesplot(f,m(1:257))xlabel('Frequency');set(handles.frequency_axes,'XMinorTick','on')grid on…
Callback from example:
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Managing Data
• Most GUIs generate or use data specific to the application
• GUI components often need to communicate data to one another
• Several basic mechanism serve this need:
– UserData property
– Application data (getappdata, setappdata, isappdata, rmappdata)
– Using the handles structure (guidata)
– Nested functions
• It is also possible to make several different GUIs work together
– Communicate by setting each other’s properties or by returning outputs
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Image Processing Modular Tools
• Many of the interactive tools of the Image Processing Toolbox are modular and can be combined into your custom GUI
– For image processing applications
– imcontrast, imcolormaptool, imcrop, imdisplayrange, imdistline, imageinfo, immagbox, imoverview, impixelinfo, impixelregion, impixelregionpanel, imsave, imscrollpane
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More Information
• MATLAB user manuals – Graphics, 3-D Visualization, Creating Graphical User Interfaces, Image Processing Toolbox, Image Acquisition Toolbox, Video and Image Processing Blockset, …
• Marchand P., Holland T. O., Graphics and GUIs with MATLAB, 3ed, 2003, CRC Press
• Smith T. S., MATLAB Advanced GUI Development, 2006, Dog Ear Publishing
Documents from Mathworks can be found at:http://www.mathworks.com/access/helpdesk/help/techdoc/
Most of this info can also be found in MATLAB Help
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